Code tracking loop with automatic power normalization

ABSTRACT

The present invention is for a receiver incorporated into User Equipment (UE) or base stations of a code division multiple access (CDMA) communication system. The UE and base station are in communication with one of the plurality of base stations and receives a communication signal through the receiver. The communication signal is correlated using a delay locked code tracking loop, that estimates and tracks a channel delay. The tracking loop comprises a reference code generator and an interpolator for generating timed signal versions in response to said communication. A timed signal correlator, included in the tracking loop for correlating at least two of the timed signal versions with the code reference signal. The result of the correlation is used for generating an error signal. An automatic power normalization loop (APN), that is responsive to the interpolator, generates a power error signal that normalizes the error signal through a normalization circuit.

CROSS REFERENCE TO RELATED APPLICATIONS

The application is a continuation of U.S. patent application Ser. No. 10/686,057, filed Oct. 14, 2003, which is a continuation of U.S. patent application Ser. No. 10/252,640, filed Sep. 23, 2002, which is a continuation of U.S. patent application Ser. No. 10/034,867, filed Dec. 27, 2001, now U.S. Pat. No. 6,456,648, issued Sep. 24, 2002, which claims priority from U.S. Provisional Patent Application No. 60/326,308, filed Oct. 1, 2001.

BACKGROUND

The present invention relates to a code tracking system for a receiver of a code division multiple access (CDMA) communication system. More specifically, the present invention relates to a second order code tracking system for more effectively removing the timing difference between the transmitted code and the received code.

Synchronization is an important task in any kind of telecommunication. There are several levels of synchronization, such as, carrier, frequency, code, symbol, frame and network synchronization. In all these levels, synchronization can be distinguished into two phases, which are acquisition (initial synchronization) and tracking (fine synchronization).

A typical wireless communication system sends downlink communications from a base station to one or a plurality of User Equipments (UEs) and uplink communications from UEs to the base station. A receiver within the UE works by correlating, or despreading, the received downlink signal with a known code sequence. The sequence must be exactly synchronized to the received sequence in order to get the maximal output from the correlator. The receiver should be able to easily adapt to a change in the environment of a radio line changing without ceasing operation. In order to accomplish this, present receivers gather as much of the transmitted signal energy as possible in order to maximize the signal-to-noise ratio. In multi-path fading channels, however, the signal energy is dispersed over a certain amount of time due to distinct echo paths and scattering. One crucial task of the receiver is thus to estimate the channel to improve its performance. If the receiver has information about the channel profile, one way of gathering signal energy is then to assign several correlator branches to different echo paths and combine their outputs constructively, a structure known as the RAKE receiver.

The RAKE receiver has several fingers, one for each echo path, and in each finger, the path delay with respect to some reference delay such as a direct or the earliest received path, must be estimated and tracked throughout the transmission. The estimation of the paths initial position in time is obtained by using a multi-path search algorithm. The multi-path search algorithm does an extensive search through correlators to locate the paths with a chip accuracy. After these initial positions are found, the tracking units generate accurate estimates for the delays of several multi-path components by means of early-late timing error detectors and utilize these estimates for the different delays to shift the phase of the codes. This type of tracking unit is known as an early-late gate synchronizer. A delay-locked loop (DLL) is commonly used to implement the early-late gate synchronizer. Illustrated in FIG. 1 is a block diagram of this delay-locked loop. The bandwidth of the Code Tracking Loop (CTL) determines the noise filtering capability of the synchronizer. The narrower the bandwidth, the more robust the synchronizer is to distortion from noise and less sensitive to small signal changes. The bandwidth of the loop depends on the parameters of the loop filter (alpha, beta), total loop gain (K_(T)), and input signal power level (P_(in)). Damping ratio of the loop also depends on the same parameters. Damping ratio of the loop determines the stability of the loop. Although the parameters of the loop can be fixed, it is very difficult to fix the input signal level.

Most of the digital receivers employ some form of Automatic Gain Control (AGC) in their physical layers. Although AGC limits the input signal level, the dynamic level of the signal level is still large. This is due to the fact that AGC is actually designed to prevent the Analog to Digital Converter (ADC) from entering saturation.

Since the dynamic range of the input signal level is not effectively limited, the bandwidth and damping ratio of the code tracking loop changes with input signal power. This results in degradation in performance for the code tracking loop.

Accordingly, there exists a need for a code tracking loop that maintains the bandwidth and damping ratio of the loop regardless of changes with the input signal power level.

Other objects and advantages of the present invention will become apparent after reading the description of the preferred embodiment.

SUMMARY

The present invention is a receiver, included in a user equipment (UE), of a code division multiple access (CDMA) communication system which includes the UE and a plurality of base stations. The UE is in communication with one of the plurality of base stations and receives a communication signal from the base station through the receiver. The communication signal is correlated by said receiver using a delay locked code tracking loop, that estimates and tracks a channel delay of the communication signal. The tracking loop comprises a reference code generator for generating a reference code signal and an interpolator for generating timed signal versions in response to the receipt of said communication. A timed signal correlator, also included in the track loop for correlating at least two of the timed signal versions with the code reference signal. The result of the correlation is used for generating an error signal. An automatic power normalization loop (APN), which is responsive to the interpolator, generates a power error signal that is used to normalize the error signal through a normalization circuit.

BRIEF DESCRIPTION OF THE DRAWING(S)

FIG. 1 is a block diagram of a prior art delay-locked tracking loop.

FIG. 2 is a block diagram of a delay-locked code tracking loop with automatic power normalization in accordance with the present invention.

FIG. 3 is a flow diagram of the delay-locked code tracking loop of the present invention.

FIG. 4 is a block diagram of an exemplary loop filter included in the delay-locked tracking loop of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

The preferred embodiment will be described with reference to the drawing figures wherein like numerals repeat like elements throughout.

Illustrated in FIG. 2 is a block diagram of the delay-locked code tracking loop (DCTL) 10 in accordance with the preferred embodiment of the present invention. The DCTL comprises an interpolator 11, two integrate and dump devices 12 a, 12 b, two squaring devices 13 a, 13 b, a normalization device 14, a loop filter 15, a code generator 16, an accumulator 17, a limiter 18, a quantizer 19, a gain circuit 9, and an automatic power normalization loop (APN) 20. The delay-lock code tracking loop 10 receives an input signal x (t−T), where T is the timing error in the received signal. Since the timing error is confined to −Tc to Tc, where Tc is the chip duration using the multi-path search algorithm, the only way to shift the incoming signal is by using mathematical interpolation. Accordingly, the interpolator 11, coupled to the integrate devices 12 a, 12 b, the code generator 16, and the APN 20, receives the input signal x (t−T) and creates three outputs: Punctual, Early and Late. As those skilled in the art know, the Early and Late outputs are a half chip early and a half chip late versions of the punctual output, respectively. They are all obtained by interpolation of the incoming signal x (t−T). After the interpolator 11, down-sampling takes place, all three outputs are preferably down-sampled by an over-sampling ratio of the transmitted signal. The punctual output is the main output of the DCTL 10, the early and late outputs are used only inside the code tracking loop 10 algorithm.

The early and late signals are correlated with the output of the reference code generator 16, such as a pilot code generator, in lower and upper branches of the DCTL using the integrate devices 12 a, 12 b, respectively. Once the outputs of the code generator 16 and the early and late outputs have been correlated, the correlated signals are forwarded to squaring devices 13 a, 13 b, respectively. Since phase synchronization is not acquired at this stage, squaring is used to obtain non-coherent CTL.

After correlation and squaring, the difference of the two branches (early and late) are taken to produce an error signal e(t), which is proportional to the timing error. The error signal e(t) is then power normalized against a power error signal (P_(e)) by the normalization circuit 14 (to be disclosed hereinafter) and output to the loop filter 15.

The loop filter 15, coupled to the normalization device 14 and the accumulator 17, filters the normalized error signal e(t) and forwards it to the accumulator 17. An exemplary loop filter is a classical proportional integrator (PI) filter, but any first order low-pass filter would be appropriate for the present invention. The PI filter, including a loop filter accumulator 41, has two branches, as shown in FIG. 4. One branch creates a control signal proportional to the current value of the error signal and the other branch produces a signal proportional to the average value of the error signal. These signals are combined after being multiplied by two different constants, alpha and beta. The accumulator 41 inside the PI filter works exactly the same way as the accumulator 17 described below.

The accumulator 17, coupled to the loop filter and a gain circuit 9, receives the filtered error signal from the loop filter 15 and processes the signal. Those having skills in the art know that the accumulator 17 simply adds its current input to its previous output. Initially, the output of the accumulator 17 is set to zero. There is an overflow detection inside the accumulator to limit the output value. The accumulation by the accumulator 17 together with the loop filter 15 is used to obtain the second order feedback loop response. The accumulator 17 then forwards the error signal e(t) to the gain circuit 9.

The gain circuit 9, coupled to the accumulator 17 and a limiter circuit 18, receives the output of the accumulator 17 and adjust the level of the filtered signal to match the interpolator 11 timing shift value. This circuit changes the sign in the timing air signal to correct the timing delay/advance of the incoming signal reference to the code generator 16. Once this is accomplished, the gain circuit 9 forwards the adjusted error signal e(t) to a limiter circuit 18 that limits the over shoot of the error signal if it is above the chip duration −Tc to Tc. The limiter 18 forwards the error signal to the quantizer 19 where the discrete value of the delay estimate is obtained and forwarded back to the interpolator 11. In this design, a thirty-two (32) level quantizer is used to obtain an accuracy of Tc/16. Although any level of quantizer can be used for different levels of delay estimate accuracy

DCTL is a second order feedback loop. In control system notation, the system function, H(s), for a second order feedback loop can be written as: $\begin{matrix} {{{H(s)} = \frac{{2{\zeta\omega}_{n}s} + \omega_{n}^{2}}{s^{2} + {2{\zeta\omega}_{n}s} + \omega_{n}^{2}}},} & {{Equation}\quad(1)} \end{matrix}$ where ζ is the damping ratio and ω_(n) is the natural frequency of the system. These can be written in terms of the parameters of the DCTL as follows: $\begin{matrix} {{\omega_{n} = \sqrt{2\sqrt{P_{in}}K_{T}\beta}},} & {{Equation}\quad(2)} \\ {{\zeta = \frac{K_{T}\alpha\sqrt{P_{in}}}{\omega_{n}}},} & {{Equation}\quad(3)} \end{matrix}$ where alpha and beta are the loop filter parameters, K_(T)=K_(S)K is the total open loop gain including the S-curve gain and the external gain, and P_(in) is the input signal power. The two-sided noise bandwidth of the system is given by $W_{L} = {{\omega_{n}\left( {\zeta + \frac{1}{4\zeta}} \right)}.}$ As an example, a Universal Mobile Telecommunications System (UMTS) Frequency Division Duplex (FDD) UE receiver design with a chip rate of 3.84 MHz and 2 times over-sampling use the following values: spreading factor of 256 for the pilot code, loop gain K=0.01, alpha=0.0141, and beta=0.00001. The values of natural frequency and damping ratio determine the main characteristics of the loop such as stability, gain and phase margins, bandwidth, convergence time, and steady state jitter. These characteristics are fixed during the design and should not change with respect to the input. Otherwise, the DCTL may malfunction and produce unexpected results. However, as seen from equations 2, 3, and 4, they all depend on input signal power, P_(in), which may change considerably during the communication process.

In order to overcome the effects of the input signal x (t−T) power level changing, an Automatic Power Normalization loop 20 (APN) is included in the delay-locked tracking loop 10 of the present invention. The APN 20, coupled to the interpolator 11, the code generator 16 and the normalization circuit 11, comprises an integrate and dump circuit 21, a squaring device 22, an adder 24, and a moving average (MA) filter 23. The punctual output from the interpolator 11 is the input to the APN loop 20. The punctual signal is received by the integrate and dump circuit 21 along with the signal from the code generator 16. The integrate and dump circuit 21 is coupled to the code generator 16, the interpolator 11, and the squaring device 22. Similar to the integrate and dump circuits 12 a, 12 b disclosed above, the integrate and dump circuit 21 correlates the punctual signal received from the interpolator 11 with the signal received from the reference code generator 16. Once the two signals are correlated the integrate circuit 21 forwards the correlated signal to the squaring device 22.

The squaring device 22, coupled to the integrate circuit 21 and the adder 24, squares the correlated signal and forwards the squared signal to the adder 24. The adder 24 subtracts the squared output from the squaring device 22 from a reference signal power (P) the reference signal power (P) is a predetermined value and is used in the design of the DLL 10 to set the parameters. As those skilled in the art know, the reference power level (P) may be any predetermined value. The subtracting of the squared signal by the adder 24 results in a power difference signal, which is forwarded to the moving average filter 23.

The Moving Average (MA) filter 23, coupled to the adder 24 and the normalization circuit 14, receives the difference signal and filters it. The MA filter 23 consists of a real valued register of size N, an adder, and a constant multiplier with a factor of 1/N. Each time a new input is passed to the MA filter 23 the register elements are shifted one to the right. The element that came the earliest (on the right most side) is cleared and the current input value is placed in the left most place in the register. After this shift, each element in the register is added. The total value is multiplied by 1/N to produce the average value for the power error signal (Pe). It is preferable that N be selected to be twenty (20), which corresponds to 20 symbols processed. The MA filter size is selected such that it will be insensitive to instantaneous power changes due to fading, however it will compensate for the average input signal level changes. Once the MA filter 23 filters the power difference signal, a filtered power error signal P_(e) is forwarded to the normalization circuit 14.

The normalization circuit 14, coupled to the squaring devices 13 a, 13 b and the APN 20, receives the error e(t) corresponding to the difference between the late and early outputs of the interpolator 11 and the power error signal P_(e) from the APN 20. In order to normalize the error signal e(t) against the power error signal P_(e), the normalization circuit 14 multiplies the error signal e(t) by (P/(P+P_(e))), where P is the referenced signal power level used in the APN loop 20.

The normalization of the error signal instead of the input signal results in a reduced number of multiplications (normalization) by a factor equal to the spreading factor. Preferably, integrated into the normalization circuit there is a limiter (not shown) that limits the multiplication factor from 0.1 to 10 or −20 dB to 20 dB. This limiter is used to prevent noise amplification.

The flow diagram of the delay-lock code tracking loop in accordance with the preferred embodiment of the present invention is illustrated in FIG. 3. An input signal in received by the DLL circuit 10 (step 301). The interpolator 11 of the DLL circuit 10 produces the late, early and punctual outputs (step 302). The late and early outputs are correlated with the code generator 16 (step 303 a), and the difference between the correlated signals is determined, producing an error signal e(t) (step 304 a). Simultaneous to the late and early outputs, the punctual output is correlated with the code generator (step 303 b) and subtracted from a predetermined reference power level to produce a power level difference signal (step 304 b). The power level difference signal is then filtered to produce a power level error signal Pe (step 305 b). The error signal corresponding to the late and early outputs, is normalized against the power level error signal Pe from the APN loop 20 (step 306). The normalized error signal is then processed to produce a delay estimate (step 307) which is forwarded back to the input of the DLL tracking loop 10 (step 308).

While the present invention has been described in terms of the preferred embodiment, other variations which are within the scope of the invention as outlined in the claims below will be apparent to those skilled in the art. 

1. A user equipment (UE) for use in a code division multiple access (CDMA) communication system including at least one base station, comprising: a receiver for receiving a communication signal from at least one base station; and a delay-locked code tracking loop (DCTL) for estimating and tracking a channel delay of said received communication signal, the DCTL comprising: a reference code generator for generating a reference code signal; an interpolator for generating a punctual output signal, an early output signal and a late output signal; a first timed signal correlator for correlating said early output signal with said reference code signal to generate a first correlated signal; a second timed signal correlator for correlating said late output signal with said reference code signal to generate a second correlated signal; a third timed signal correlator for correlating said punctual output signal with said reference code signal to generate a third correlated signal; an adder for combining the first and second correlated signals to generate a first error signal; an automatic power normalization (APN) loop for generating a second error signal based on said third correlated signal; and a normalization circuit for normalizing said first error signal by using said second error signal to generate a third error signal used for controlling the generation of the punctual output signal by the interpolator.
 2. The UE of claim 1, wherein said APN includes: an adder for subtracting said third correlated signal from a power reference signal, to produce a power difference signal; and a filter, responsive to said adder, for filtering said power difference signal to generate said second error signal.
 3. The UE of claim 2 further comprising: a loop filter, coupled to said normalization circuit, for filtering said third error signal; an accumulator, responsive to said loop filter, for accumulating said third error signal; a gain circuit, coupled to the accumulator, for changing the sign in said third error signal to correct a timing delay/advance of the received communication signal to the reference code signal; and a quantizer for generating a discrete value of the delay/advance for controlling the generation of the punctual output signal by the interpolator.
 4. The UE of claim 3, wherein said early output signal is a half chip earlier than said punctual output signal and said late output signal is a half chip later than said punctual output signal.
 5. The UE of claim 3, wherein the loop filter is a first order low-pass filter.
 6. The UE of claim 3, wherein the loop filter is a classical proportional integrator (PI) filter.
 7. The UE of claim 3, wherein the accumulator is equipped with overflow detection to limit the output value of the accumulator.
 8. The UE of claim 3, wherein the quantizer is a 32 level quantizer for obtaining an accuracy of Tc/16, where Tc is the chip duration using the multi-path search algorithm.
 9. The UE of claim 1, wherein the APN further includes a limiter for preventing noise amplification.
 10. The UE of claim 9, wherein the limiter limits the multiplication factor from 0.1 to
 10. 11. The UE of claim 9, wherein the limiter limits the multiplication factor to −20 dB to 20 dB. 